Brown Dwarf Companions to Young Solar Analogs: An Adaptive Optics Survey Using Palomar and Keck Thesis by Stanimir A. Metchev In Partial Fulfillment of the Requirements for the Degree of Doctor of Philosophy California Institute of Technology Pasadena, California 2006 (Defended August 18, 2005) ii c 2006 Stanimir A. Metchev All Rights Reserved iii Acknowledgements Stan, congratulations. I just can’t believe you made it. Cheers, Jeff Hickey Having left this for last, I now finally have the peace of mind and hindsight to recollect and thank all the people that supported me, guided me, and kept me sane throughout my graduate work. First and foremost are my parents, Anguel and Kalitchka, whom I have rarely seen for more than 2 weeks a year over the past 10 years, but whose faith in me has always pushed me forward, even from the distance of my home country, Bulgaria. I thank my father for showing me the stars and making me aware of a Universe open to endless exploration. I thank my mother for her unconditional support, even when she thought that I should have taken up Economics, rather than Astronomy. My parents and my brother, Anton, are the three people in this world that have defined how I think, feel, and love. The people that are to blame for my choice of career are the scientists and staff at the Nicolai Copernik National Observatory in my home-town of Varna: Vesselka Radeva, Zahari Donchev, Eva Bojurova, Petar Slavov, Ivan Ivanov, Rudi Kurtev, and the president of amateur astronomy club “Canopus,” Valentin Velkov. The guiltiest among them are Vesselka and Valentin—they loaded me with a life-long supply of enthusiasm for astronomy, at the early age of 10. My graduate advisor, Lynne Hillenbrand, is the person to whom I owe by far the most for my subsequent development as a scientist. I feel very fortunate to have been taken on as her student. Lynne’s balance of encouragement and criticism, her ability to manage while allowing independence, and her camaraderie with her students form a rare ensemble of qualities in an advisor, with the benefits of which I hope to endebt my own students one day. For their scientific advice and objectivity (I hope) of judgment, I extend my sincere grat- itude to the past and present members of my thesis committee: Lynne Hillenbrand, Andrew Blain, Shri Kulkarni, Richard Dekany, Re’em Sari, and David Stevenson. I have benefited from multiple discussions and guidance from every one of them, even before they were confronted with the present tome. I have also been fortunate to be fully immersed in the Formation and Evolution of Planetary Systems (FEPS) Spitzer Legacy team, which combines a unique array of theoretical and obser- vational expertise on topics ranging from young stars and circumstellar matter to space-based imaging and high-resolution spectroscopy. Among the members and associates of the team that have been most influential on me, I single out Lynne Hillenbrand (again), Michael Meyer, Russel White, Sebastian Wolf, and John Carpenter, with whom I have had the pleasure to work in close collaboration. John also developed and maintains the FEPS team database, that has been of central importance in managing the large volume of data compiled in this thesis. The quality of the data gathered for this work would have paled in comparison to its present state, had it not been for the dedication and professionalism of the Palomar and Keck adaptive optics (AO) teams, lead by Mitchell Troy, Richard Dekany, and Peter Wizinowich. Multiple discussions with Mitch and Rich, as well as with Tom Hayward, Matthew Britton, Hal Petrie, Keith Matthews, David Thompson, Randy Campbell, David Le Mignant, and Marcos van Dam have helped me overcome my initial frustrations with the complexity of AO and become a proficient AO user, excited about the tremendous possibilities offered by the technology. Rich and Hal also helped me design the Palomar AO astrometric experiment that proved crucial iv for the successful completion of the present work in a timely fashion. Keith provided the astrometric mask for the experiment, as well as key insights for interpreting the experiment data. Keith and David were also exceptionally kind in obtaining science observations for the present work on several occasions. The Palomar 200-inch telescope was the backbone for my thesis research. With more than 70 nights spent at the observatory during my 5 years at Caltech, I am very grateful to the people who made me want to go back there every time: Dipali and Rose for the warm hospitality and the delicious meals at the Palomar Monastery; Jean Mueller and Karl Dunscombe for their professionalism at the telescope controls and for putting up with my erratic choices of music late at night; Rick Burress and Jeff Hickey for their selfless dedication to ensuring the flawless performance of the Palomar AO system, and Jeff—for the excellent email greeting on the day of my defense, quoted at the beginning; Steve, Greg, Dave, John, and the rest of the Palomar day-crew for routinely doing the huge amount of work that it takes every day to keep the observatory running and the astronomers happy. With this I come to my close friends. I thank all of you who kept me sane over the years and months before my defense, who came to support me during the defense itself, and who celebrated with me afterwards. In particular, I need to acknowledge my office mates Dave Sand, Kevin Bundy, and Josh Eisner. Between them and Russel White, there would always be a good occasion for mid-week drinks at Amigos or at Burger Continental. Also, having gone through the job-hunting and thesis ordeals at the same time as Josh and Dave has certainly helped me maintain focus and keep the pace. My close friendship with Alex “Dude” Williamson and the warm hospitality of the Williamsons and the Redferns has been a staple of my American experience. Alex, Jon, Sue, and Drew Williamson, and Greg, Laurie, Rachel, and Dan Redfern: thank you all for being my family away from home. Finally, there is one person who saw and heroically put up with the worst of it, and whose down-to-earth view on life carried me through. My lovely future wife, Anne Simon. I owe you an enormous debt of love and patience. Having you beside me over the past 4 years has given me a balance that I had never attained before. v Abstract We present results from an adaptive optics survey conducted with the Palomar and Keck tele- scopes over 3 years, which measured the frequency of stellar and sub-stellar companions to Sun-like stars. The survey sample contains 266 stars in the 3–10000 million year age range at heliocentric distances between 8 and 200 parsecs and with spectral types between F5–K5. A sub-sample of 101 stars, between 3–500 million years old, were observed in deep exposures with a coronagraph to search for faint sub-stellar companions. A total of 288 candidate companions were discovered around the sample stars, which were re-imaged at subsequent epochs to deter- mine physical association with the candidate host stars by checking for common proper motion. Benefiting from a highly accurate astrometric calibration of the observations, we were able to successfully apply the common proper motion test in the majority of the cases, including stars 1 with proper motions as small as 20 milli-arcseconds year− . The results from the survey include the discovery of three new brown dwarf companions (HD 49197B, HD 203030B, and ScoPMS 214B), 43 new stellar binaries, and a triple system. The physical association of an additional, a priori-suspected, candidate sub-stellar companion to the star HII 1348 is astrometrically confirmed. The newly-discovered and confirmed young brown dwarf companions span a range of spectral types between M5 and T0, and will be of prime significance for constraining evolutionary models of young brown dwarfs and extra-solar planets. Based on the 3 new detections of sub-stellar companions in the 101 star sub-sample and following a careful estimate of the survey incompleteness, a Bayesian statistical analysis shows that the frequency of 0.012–0.072 solar-mass brown dwarfs in 30–1600 AU orbits around young +8.3 solar analogs is 6.8 4.9% (2σ limits). While this is a factor of 3 lower than the frequency of stellar companions− to G-dwarfs in the same orbital range, it is significantly higher than the frequency of brown dwarfs in 0–3 AU orbits discovered through precision radial velocity surveys. It is also fully consistent with the observed frequency of 0–3 AU extra-solar planets. Thus, the result demonstrates that the radial-velocity “brown dwarf desert” does not extend to wide separations, contrary to previous belief. Contents 1 Introduction 1 1.1 Brown Dwarfs: A Brief Summary of Properties . ....... 2 1.1.1 SimilaritiestoStars . .. .. .. 2 1.1.2 SimilaritiestoPlanets . ... 5 1.1.3 A Matter of Terminology: Low-mass Brown Dwarfs vs. Planets ..... 5 1.1.4 Theoretical Models of Sub-stellar Evolution . ......... 6 1.2 How Frequent are Brown Dwarf Companions and Why Study Them? ...... 7 1.3 Observational Challenges and Constraints . .......... 10 1.4 TheObservationalApproachataGlance . ...... 12 1.5 ThesisOutline ................................... 13 2 Survey Sample 14 2.1 Overview ....................................... 14 2.2 SelectionCriteria ............................... .... 15 2.2.1 Spectral Types and Stellar Masses . .... 15 2.2.1.1 Spectral Types: Dependence on Color, Reddening, and Surface Gravity ............................... 15 2.2.1.2 Masses: DependenceonAge . 17 2.2.2 StellarAges .................................. 18 2.2.3 DistancesandProperMotions .
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